DE10117695A1 - Method for packet-oriented transmission of data in a communication system - Google Patents

Abstract

The invention relates to a method for the transmission of data blocks between radio stations in a radio communication system, whereby data blocks are sent from a first radio station in a number of channels and the receipt of at least two data blocks is confirmed in a common channel by a second radio station.

Description

The invention relates to a method for packet-oriented Transmission of data in a communication system, esp in particular a radio communication system or mobile radio system using a pure or hybrid ARQ file procedure for testing for transmission errors and repeated requests incorrect and / or missing Da tenpakete.

In a radio communication system, data is transmitted using elec tromagnetic waves transmitted. The blasting of the elec tromagnetic waves occur with carrier frequencies, those in the frequency band provided for the respective system lie. Connections between fixed base stations and subscriber stations, the can be fixed, mobile radios, built and triggered.

To meet the needs of the available spectrum of Trä synchronous multiplex proceed z. B. on the basis of a frequency, time, space and / or code-selective multiple access for the purpose of distribution the transmission capacity of a physical channel introduced several connections. If further the term "physical channel" or "channel" is used, so it is identical to the term "resource" used against possibly also over several physical channels, each a certain bit transmission rate on the air interface provides.  

A disadvantage of the synchronous multiplex method is that the for a connection used transmission capacity due to the time synchronization for a longer period is firmly bound and even if there are currently no transfers capacity is not required for other participants can be released. This leaves transmission capacity may not be used.

This deficiency is further improved on another packet-based transmission-based process, the Pa ketvermittlung. The packet switching is also based on the sharing of one physical channel among several Links. There is also a subdivision for this Timeline, but not as with synchronous multiplex procedure, ostensibly in fixed time slots, but in addressed data packets of variable length. The data will transmitted time variant, which is why you can also from an asynchro NEN multiplexing speaks. A data packet is also called (Data) block, (data) frame, frame or (data) word be records.

Every participant in the radio communication system can do everyone time towards the previously unused transmission capacity grab and its data packets z. B. after the stochastic Transfer access procedure to ALOHA. In addition, the Bit transfer rate of a connection very easily infinitely vary. A subscriber station can do the bit transmission guess both by the time intervals in which the Da ten packets are sent, as well as by their length influence. Future radio communication systems, like at for example the UMTS (Universal Mobile Telecommunications Sy stem), the participants will have a variety of different  Offer services with different bit transfer rates. In addition to the pure voice transmission, multimedia applications with the associated variety of services, such as the Internet, Voice over IP (Internet telephony), e-mail, SMS (Short Mes say service = short message service from point to point) and make up a large part of the data volume. The Integration of packet-oriented transmission is special here promising.

The air interface is one of the least favorable communications onsmedia that occur in communications engineering. A pro Short-term drop in reception level and signal ver strains that occur in the event of transfer of the above Struk data can lead to loss of data. Disturbed data pa kete are generally not kor from the receiving station rigged and then accepted, but by means of an error identifying codes, possibly in addition to the correction, for errors checked. If a data packet is recognized as faulty, then it will be requested again from the sending station. To do this generally a data packet to be transmitted with an acknowledgment (Ackknowledgement) confirmed. For a faultlessly received Data packet is given a positive acknowledgment (ACK = Acknowledge) transmit the transmitting station. If the received data packet is faulty, a negative receipt (NAK = Negative Acknowledge) to the transmitting station and its renewed Transfer requested. The transmitter station must therefore have a Manage a copy of the transmitted data packet until it is has been reported as received without errors. This as ARQ procedure (ARQ = Automatic Repeat Request) known mistake However, the treatment process sets a back channel between ahead of the sending station and the receiving station the results of the error evaluation by the correspond Acknowledgment from the receiving station to the transmitting station  be communicated. On this back channel are also the front mentioned data for measuring the channel quality, such as transmission transmission rate, reception power, transmission power and / or interference transmit limits, which means additional transmission capacity and computing power is tied up during a connection. In In practice, the ARQ data backup procedure is also used with ei ner error forward correction (FEC = Forward Error Correetion) combined and then referred to as the hybrid ARQ process. As the clear when using ACKs / NAKs as receipts Assignment to a data packet is not always guaranteed you can use the number of the next one expected packet (Request Number = RN) and their repetition Request (RQ) as a receipt. Depending on the ARQ signaling can be an RN as positive or nega tive receipt and an RQ as negative quit tung.

An overview of ARQ signaling z. BM Bos sert, M. Breitbach: Digitale Netze, BG Teubner Stutt gart.Lepzig 1999 , pp. 141-162.

A well-known hybrid ARQ process is the so-called N-Ka Stop and Wait HARQ (N-channel SAW HARQ). This method uses N superimposed simple stop and wait HARQ-In punch. For example, the so-called 2-channel stop and Wait HARQ realized in such a way that during the Emp data blocks of a second channel are received Data blocks of the first channel are confirmed or that wäh After receiving data blocks of the first channel of the Emp beginning of the data blocks of the second channel are confirmed. This enables the transfer of data blocks to the Emp catcher while this checks whether the previously sent data blocks were received incorrectly and thus retransmitted  are. Through this realization, Ver Delays in the acknowledgment of receipt are reduced the.

In the same way, N-channel SAW HARQ methods are also included for example N = 4, 6. , , conceivable that depend largely on Memory requirements and computing power in the base stations or subscriber terminals is selected. This procedure together, however, is an immediate confirmation of the success Chen or unsuccessful receipt of a data block, where due to signaling load, especially for a broadband Packet data channel for a large number of parallel connections adversely increased.

The object of the invention is in a use described SAW ARQ method a number of required Return channels to signal the acknowledgment of receipt to the right duce.

The task is accomplished by a process according to the characteristics of the Claim 1 solved. A through communication system management of the method is specified in claim 6. Advantageous further developments are in the dependent patent sayings.

According to the invention from a receiving radio station Be confirmation signaling of several received data blocks in a common confirmation channel to the sending radio station signals.

This can advantageously, for example, several radio stations tions use a common confirmation channel, whereby Radio resources can be used efficiently.

Based on an embodiment, the invention will follow explained below.

Show

Fig. 1 is a block diagram of a radio-Kommunikationssy stems, in particular of a known GSM mobile radio system,

Fig. 2 is a flow diagram of the N-channel SAW ARQ method according to the prior art, and

Fig. 3 is a flow diagram of the N-channel SAW ARQ method according to the invention.

Fig. 1 shows a block diagram of a radio communication system, especially a known GSM mobile radio system. However, this structure can be transferred in a simple manner to other systems, such as the UMTS mobile radio system, in which the invention can also be implemented.

The GSM mobile radio system consists of a large number of mobiles exchanges MSC (Mobile Switching Center), the one Transition to a fixed landline network PSTN possible chen. Each MSC is with a variety of base station controllers BSC (Base Station Controller) connected, each with a central administration of radio sources for one or more base stations carry out. The base stations BS in turn enable one Connection to a variety of subscriber stations MS via a radio interface corresponding to a specific part nehmerseparierungsverfahren. After a transfer supply in the upward direction UL (uplink) from the subscriber stations  MS to the base station BS or the downlink DL (Downlink) from the base station BS to the subscriber stations MS distinguished. At least through each base station BS a radio cell Z ge supplied with radio resources forms. The subscriber stations MS are, for example, as mobile radio stations or as a fixed wireless network end devices, for example of a wireless subscriber locking system (Access Network). The Mobilver MSC is still operating and Maintenance center OMC (Operation and Maintenance Center) ver bound, in which important parameters of the system are administered and that represents a human-machine interface.

On the radio interface between the base station BS and the subscriber stations MS are signaling information and user data of different services. So are from the base station BS for example in a speci fish general organizational channel B (BCCH - broadcast Control Channel) general information regarding the organization nization of the mobile radio system sent periodically by the subscriber stations MS are evaluated. exemplary are from the base station BS in a physical channel ch data blocks or data packets DP in the downward direction to the Subscriber station MS sent, the error-free or faulty reception with a confirmation ACK (acknowledge ledged) or non-confirmation message NAK (not acknowled ged) in the upward direction UL to the base station BS signali Siert. The data is transferred in the same way blocks from the subscriber station MS to the base station BS.

In FIG. 2, a flowchart for an N-channel SAW HARQ method described in the introduction to the description is given by way of example with reference to FIG. 1. The method described below is based on the assumption that the channel for the transmission of the data blocks is structured according to a time multiplex method. The base station BS transmits fr1 in a respective time frame. , , Data blocks DP1. , , to the receiving subscriber station MS. While this checks whether the previously sent data blocks have been received incorrectly and are therefore to be retransmitted, the base station B5 is already sending subsequent data blocks DP2. , , During this time, the signaling from the subscriber station MS to the base station BS is carried out as to whether the data blocks have to be sent repeatedly or whether new data blocks can be sent by means of a respective signaling message A / N (Acknowledged / Not Acknowledged) with the indication of the respective data block DP. For a 2-channel SAW HARQ, corresponding to N = 2, the receiver only has to decide the duration of a time frame for time and to signal whether it is necessary to send the data block again. Depending on this decision, the data block is sent again or a new data block is sent in the third time frame fr3.

The exemplary flow chart of FIG. 3 is based on the inventive idea that the confirmation signaling in a common return channel in the upward direction UL follows. A joint confirmation signaling of several data blocks in a time frame according to the invention enables several subscriber stations to use a common confirmation channel or return channel.

Uses the variant shown as for one described 4-channel SAW HARQ process four channels ch1. , .ch4, that's too note that the processing time to determine the wrong ler-free or faulty reception of the time of a 2-Ka nal corresponds to the SAW HARQ process. The data block DP1, the  in the time frame fr1 would only have to be broadcast in the Time frame fr5 can be repeated or could be in the case of a wrong a new data block DPx is sent the. The data block DP2 would in the same way in the Time frame fr6 repeated or a new data block sent become.

Accordingly, as shown, the confirmation is sufficient signaling for the data blocks DP1 and DP2 in the third timeframe fr3. It is also conceivable the signaling only in the fourth time frame fr4 feed to the recipient a long time to edit and to provide evaluation. However, this sets assuming that the transmitter is then able to subsequent fifth time frame for fr5 repeated or new send.

The advantage lies in the saving of radio resources. This is up to 50% in the example of 4-channel SAW HARQ the feedback is always sent together for two data blocks becomes. Since each receiver of data blocks be a return channel If necessary, this variant can be the number of parts that can be supplied Increase subscriber stations in a radio cell. In addition can the interference caused by the feedback is reduced become.

The variants are not limited to 4-channel SAW HARQ. For more than four channels, both the transmitter as well a longer processing time is available to the recipient hen and the number of required radio channels would still be small ger.  

Essential criteria for switching between under Different procedures are the characteristics of the participants stations as well as the base station. Especially the ability Keeping the processing time short decides whether 2-Ka nal SAW HARQ or the variant of the 4-channel SAW HARQ which Saves radio channels, is used. Is the processing time not sufficiently low, the 4-channel SAW HARQ variant can to be used.

Another criterion for switching is the amount of possible data to be transmitted. Are only a few data on the emp can be transferred to the 2-channel SAW HARQ Vari ante can be switched. This reduces the time between the receipt of the data blocks and the feedback to the sender in the return channel.

Depending on the mentioned and possible further criteria can be the most suitable variant of the N-channel SAW HARQ Procedure can be selected. Which variant was selected is communicated by means of a signal.

Claims (6)

1. Method of transferring data blocks (DP) between Radio stations (BS, MS) in a communication system in which from a first radio station (BS, MS) data blocks (DP1...) in a number of channels (ch1...) are sent, and from a second radio station (MS, BS) the reception of at at least two data blocks confirmed in a common channel becomes. 2. The method according to claim 1, wherein the transmission of the data blocks (DP) according to an ARQ Procedure is carried out. 3. The method according to claim 2, wherein a hybrid ARQ method is used. 4. The method according to any one of claims 1 to 3, in which the channels for the transmission of the data blocks (DP) according to one Time division multiplexing are structured. 5. The method according to any one of claims 1 to 4, in which the common channel of several radio stations (MS) in time is used separately. 6. Communication system for performing the method according to Claim 1.